A mixing tool lock fixes a mixing tool in a container of a kitchen appliance, such as a stand mixer for kneading, mixing or grinding ingredients. The locking device includes a tool holder in which the mixing tool is rotatably mounted, and a fixing device for the tool holder. The tool holder also has a releasing device for releasing the mixing tool from the container. The locking device can be attached to the lower outside of a container having a bottom opening on the lower outside. The size of the opening corresponds at least to the diameter of the casing of the mixing tool so that the tool-side components of the mixing tool can be passed completely through the bottom opening from the outside. A kitchen appliance includes a drive, a housing that accommodates the drive, at least one mixing tool, and a container having the locking device.

A blender system that includes a base that is select ively and operatively engaged with a container is shown and described herein. The base may include a near field communications chip that may communicate with a near field communications chip of a container. The base also includes a motor that is selectively and operatively engaged with a blade disposed within the container.

Proposed is a blender, in which a blender body operates when closure of the container lid on a container body is detected. In the blender, when the closure of the container lid is detected, power is transmitted from a first inductive coil of the blender body to a second inductive coil of the container body. A transmission module of the container body transmits a signal to a receiving module of the blender body by suing the power transmitted to the second inductive coil. When the signal is received by the receiving module, the blender body detects the closure of the container lid and is operated.

A food processing apparatus for preparing a fluid food product includes a food processing chamber including a blade arrangement driven by a motor; a particle sensor arranged to measure an actual particle size within said fluid food product in said food processing chamber and a controller arranged to control the motor. The controller is communicatively coupled to the particle sensor and may disengage the motor in response to a signal from the particle sensor indicative of the actual particle size reaching a threshold value of no less than 400 μm within said fluid food product.

A blender using different power modes is disclosed. Exemplary implementations may include a base assembly, a container assembly, an electrical motor, a blending component, a control interface, control circuitry, and/or other components. The control circuitry may be configured to make different types of detections related to the availability and/or usage of electrical power, and may control the electrical motor using at least two different power modes of operation, thus providing different amounts of power to the electrical motor in different power modes of operation.

The present disclosure provided a food processor, a cutter set mounting structure and a stirring cup. The cutter set mounting structure includes: a container bottom, a mounting hole being provided in the container bottom; and a cutter holder mounted at the mounting hole and used for allowing a cutter of a food processor to be mounted, and the cutter holder is provided with an anti-disengagement part, an anti-disengagement matching part is arranged at the container bottom, and the anti-disengagement part matches the anti-disengagement matching part to limit the cutter holder from being disengaged from the mounting hole under the action of gravity. In the present disclosure, by means of the matching of the anti-disengagement part and the anti-disengagement matching part, the cutter holder can be prevented from being disengaged from the mounting hole under the action of gravity.

The present invention relates to a blender. The blender includes: a body provided with a motor assembly; a container which is detachably mounted to the body and in which food is accommodated; a container seating portion which is provided on a top surface of the body and on which the container is seated; a body accommodation portion which is recessed in a bottom surface of the container so that the container seating portion is inserted, and is in close contact with the container seating portion when the container is seated to fix the container; and an air vent which passes through a lower end of the container and communicates with the body accommodation portion, and through which air enters and exits the body accommodation portion when the container is mounted on the body.

A portable food processing apparatus describes a food processing chamber including a blade arrangement and a housing including a motor for driving said blade arrangement, a microcontroller for controlling said motor and at least one motion sensor communicatively coupled to said microcontroller. The microcontroller is adapted to evaluate sensor data produced by the at least one motion sensor in order to detect a predefined motion pattern in said sensor data, said predefined motion pattern corresponding to an operation setting of the motor; and control said motor in accordance with said operation setting upon detection of the predefined motion pattern.

A food preparation appliance, such as a blending, mixing, or food processing appliance, allows for rotatable blade movement by a drive and/or driven shaft relative to a jar holding contents along with movement of the jar relative to the blade in the axial direction of the drive and/or driven shaft. For example, a vertical or axial movement of the blade relative to the jar, or vice-versa can be guided within defined limits. Aspects provide the consumer with an intuitive and proactive way of preventing cavitation and improving the blending performance by allowing the user to manually and indirectly physically agitate the mixture with an up and down motion of the jar during a blending operation. This option for manual operation is part of the disclosed blender design, so is always and conveniently available to the consumer as an anti-cavitation method.

A blender system that includes a base that is selectively and operatively engaged with a container and an open and closable enclosure is shown and described herein. The base may include an interlock component that may interact with an interlock component of an enclosure or a container. The base also includes a motor that is selectively and operatively engaged with a blade disposed within the container. The motor may be controlled based on arrangement of the base, the enclosure, or the container.